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Main Authors: Silva, Nuno A., Rocha, Vicente, Ferreira, Tiago D.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.03791
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author Silva, Nuno A.
Rocha, Vicente
Ferreira, Tiago D.
author_facet Silva, Nuno A.
Rocha, Vicente
Ferreira, Tiago D.
contents Extreme learning machines explore nonlinear random projections to perform computing tasks on high-dimensional output spaces. Since training only occurs at the output layer, the approach has the potential to speed up the training process and the capacity to turn any physical system into a computing platform. Yet, requiring strong nonlinear dynamics, optical solutions operating at fast processing rates and low power can be hard to achieve with conventional nonlinear optical materials. In this context, this manuscript explores the possibility of using atomic gases in near-resonant conditions to implement an optical extreme learning machine leveraging their enhanced nonlinear optical properties. Our results suggest that these systems have the potential not only to work as an optical extreme learning machine but also to perform these computations at the few-photon level, paving opportunities for energy-efficient computing solutions.
format Preprint
id arxiv_https___arxiv_org_abs_2401_03791
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Optical Extreme Learning Machines with Atomic Vapors
Silva, Nuno A.
Rocha, Vicente
Ferreira, Tiago D.
Optics
Quantum Physics
Extreme learning machines explore nonlinear random projections to perform computing tasks on high-dimensional output spaces. Since training only occurs at the output layer, the approach has the potential to speed up the training process and the capacity to turn any physical system into a computing platform. Yet, requiring strong nonlinear dynamics, optical solutions operating at fast processing rates and low power can be hard to achieve with conventional nonlinear optical materials. In this context, this manuscript explores the possibility of using atomic gases in near-resonant conditions to implement an optical extreme learning machine leveraging their enhanced nonlinear optical properties. Our results suggest that these systems have the potential not only to work as an optical extreme learning machine but also to perform these computations at the few-photon level, paving opportunities for energy-efficient computing solutions.
title Optical Extreme Learning Machines with Atomic Vapors
topic Optics
Quantum Physics
url https://arxiv.org/abs/2401.03791